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ficus_carica_l [2017/04/02 10:20] andreas |
ficus_carica_l [2021/12/20 11:56] andreas |
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"In general, aldehydes and terpenes were the major volatile group responsible aroma for peels and pulps in fig fruits. Total aldehydes were higher in pulps than peel in all cultivars. However total terpenes were higher in peel rather than in pulp. Among terpenes, β-caryophyllene were the major volatile compounds found in both peel and pulp. Phenol, 2,6-bis (1, | "In general, aldehydes and terpenes were the major volatile group responsible aroma for peels and pulps in fig fruits. Total aldehydes were higher in pulps than peel in all cultivars. However total terpenes were higher in peel rather than in pulp. Among terpenes, β-caryophyllene were the major volatile compounds found in both peel and pulp. Phenol, 2,6-bis (1, | ||
[Volatile compounds determined by HS/GC-MS technique in peel and pulp of fig (Ficus carica L.) cultivars grown in Mediterranean region of Turkey., Gozlekci, S., Kafkas, E., Ercisli, S., Notulae Botanicae Horti Agrobotanici Cluj-Napoca, | [Volatile compounds determined by HS/GC-MS technique in peel and pulp of fig (Ficus carica L.) cultivars grown in Mediterranean region of Turkey., Gozlekci, S., Kafkas, E., Ercisli, S., Notulae Botanicae Horti Agrobotanici Cluj-Napoca, | ||
+ | |||
+ | Main volatile components of pollinated or non-pollinated figs were 3-hydroxy-2-butanone (acetoin; up to ~36% non-pollinated, | ||
+ | " | ||
+ | [Trad, Mehdi, et al. "Does pollination affect aroma development in ripened fig [Ficus carica L.] fruit?" | ||
Major volatile compound found in dried figs was benzaldehyde (24.7%), followed by hexanal (23.8%), furfural (9.6%), 3-methyl butanal (5.7%), 2-methyl butanal (4.0%) and pentanal (3.8%). Ethyl acetate (2.9%) was the most abundant ester found in dried figs, along with minor (0.1-0.5%) amounts of ethyl esters of C4/C5 acids. Other components were 2-pentyl furane (2.9%), 2-ethyl furane (0.9%), butyrolactone (2.2%), ethanol (1.1%) and δ-decalactone (0.2%). Pretreatment of figs with ascorbic acid, sulfur dioxide or citric acid decreased significantly the drying time, but had great influence on aroma volatiles by lowering furfural (4.8-5.5%) and making ethyl acetate a major component (19-55%).\\ | Major volatile compound found in dried figs was benzaldehyde (24.7%), followed by hexanal (23.8%), furfural (9.6%), 3-methyl butanal (5.7%), 2-methyl butanal (4.0%) and pentanal (3.8%). Ethyl acetate (2.9%) was the most abundant ester found in dried figs, along with minor (0.1-0.5%) amounts of ethyl esters of C4/C5 acids. Other components were 2-pentyl furane (2.9%), 2-ethyl furane (0.9%), butyrolactone (2.2%), ethanol (1.1%) and δ-decalactone (0.2%). Pretreatment of figs with ascorbic acid, sulfur dioxide or citric acid decreased significantly the drying time, but had great influence on aroma volatiles by lowering furfural (4.8-5.5%) and making ethyl acetate a major component (19-55%).\\ | ||
[Characterisation of volatiles in dried white varieties figs (Ficus carica L.)., Mujić, I., Kralj, M.B., Jokić, S., Jug, T., Šubarić, D., Vidović, S., Jarni, K., Journal of food science and technology, 51(9), 2014, 1837-1846] | [Characterisation of volatiles in dried white varieties figs (Ficus carica L.)., Mujić, I., Kralj, M.B., Jokić, S., Jug, T., Šubarić, D., Vidović, S., Jarni, K., Journal of food science and technology, 51(9), 2014, 1837-1846] | ||
+ | |||
+ | „The ‘key’ odor compound of dried fig aroma was found to be β-damascenone. Owing to its low detection threshold and minute quantity in fig cultivars, the presence of β-damascenone was furthermore confirmed through GC/MS/MS and GC/TOF-MS. β-Damascenone was identified in variable quantities among fig varieties and their liquors, predominating in Kalamon fig cultivar of Peloponnese region, while its amount was found to be dependent on the postharvest storage time and preservation process of dried figs.“ \\ | ||
+ | Main aroma components were e.g. esters like diethyl succinate (0-4.5%), ethyl dodecanoate (0-11.6%), and ethyl hexadecanoate (2.0-9.7%), the aldehydes benzaldehyde (1.3-5.1%) p-hydroxybenzaldehyde (0.4-2.2%), and vanillin (0.3-3.5%), aromatic acids like benzoic acid (0.4-2.5%), cinnamic acid (0.5-4.4%), and vanillic acid (2.3-16.5%), | ||
+ | [Palassarou, | ||
+ | |||
+ | "... 22 compounds were identified as the key aroma compounds and eight of these were evaluated as the most important aroma contributors of Xinjiang dried figs, including heptanal, nonanal, linalool, benzyl benzoate, styrene, eugenol, 2-methoxy-4-vinylphenol, | ||
+ | [Yao, Lingyun, et al. " | ||
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Zeile 32: | Zeile 43: | ||
**Fig leaf absolute** | **Fig leaf absolute** | ||
- | The leaves of Ficus carica are extracted with solvent to obtain a concrete, which is subsequent treated with alcohol. The residue represents a dark green to brownish green viscous liquid of a sweet, green, herbaceous, somewhat woody odor with a mossy undertone. The first distillation range (30-160°C/ | + | The leaves of Ficus carica are extracted with solvent to obtain a concrete, which is subsequent treated with alcohol. The residue represents a dark green to brownish green viscous liquid of a sweet, green, herbaceous, somewhat woody odor with a mossy undertone. The first distillation range (30-160°C/ |
- | [Kaiser, R., „New | + | [Kaiser, R., „New |
"Based on sensitization reactions at 5% and strong phototoxic reactions, the Panel concluded that the material should be banned. A RIFM Advisory Letter (RIFM, 1980) was issued to all members stating the potential for induction of skin and phototoxic reactions. As a result, an IFRA Guideline (now renamed a Standard) was issued in October, 1980 (IFRA, 1980), which stated, ‘‘Fig Leaf Absolute should not be used as a fragrance ingredient based on test results of RIFM showing sensitizing and extreme phototoxic potential for this material.’’ A RIFM | "Based on sensitization reactions at 5% and strong phototoxic reactions, the Panel concluded that the material should be banned. A RIFM Advisory Letter (RIFM, 1980) was issued to all members stating the potential for induction of skin and phototoxic reactions. As a result, an IFRA Guideline (now renamed a Standard) was issued in October, 1980 (IFRA, 1980), which stated, ‘‘Fig Leaf Absolute should not be used as a fragrance ingredient based on test results of RIFM showing sensitizing and extreme phototoxic potential for this material.’’ A RIFM | ||
Zeile 42: | Zeile 53: | ||
[Ayoub, N., Singab, A. N., Mostafa, N., & Schultze, W. (2010). Volatile constituents of leaves of Ficus carica Linn. grown in Egypt. Journal of essential oil bearing plants, 13(3), 2010, 316-321] | [Ayoub, N., Singab, A. N., Mostafa, N., & Schultze, W. (2010). Volatile constituents of leaves of Ficus carica Linn. grown in Egypt. Journal of essential oil bearing plants, 13(3), 2010, 316-321] | ||
- | {{: | + | {{: |
Masclef,A., Atlas des plantes de France, vol.3 t.289, (1893) \\ | Masclef,A., Atlas des plantes de France, vol.3 t.289, (1893) \\ | ||
[[http:// | [[http:// | ||
+ | {{http:// | ||
+ | Ficus carica \\ © Rolf Marschner (2009), | ||
+ | [[http:// |